KR101655452B1 - Electric precipitator and electrode plate thereof - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to an electrostatic precipitator for collecting contaminants such as dust by an electrical attraction and an electrode plate.
The electrostatic precipitator according to an embodiment of the present invention includes a high voltage electrode plate and a low voltage electrode plate alternately stacked to form a charging region and a dust collecting region along the air flow direction, And a dust collecting electrode disposed over the charging area and the dust collecting area so as to collect contaminants charged in the dust collecting area.

Description

ELECTRIC PRECIPITATOR AND ELECTRODE PLATE THEREOF FIELD OF THE INVENTION [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric dust collector and its electrode plate, and more particularly, to an electric dust collector for collecting contaminants such as dust by an electric attraction and an electrode plate thereof.

Generally, an electric dust collector is installed in an air conditioner or the like, and is disposed on a flow path through which air flows, and collects contaminants such as dust contained in air passing through an electric dust collector through an electric attraction .

In general, the electric dust collecting apparatus includes a charging section disposed on the upstream side in the air flow direction to charge the pollutant, and a two-stage electric dust collecting system including a dust collecting section disposed on the downstream side in the air flow direction for collecting the charged contaminants by electrical attraction To collect contaminants.

In this electric dust collecting apparatus of the two-stage electric dust collection system, the charging section includes a discharge wire which is formed in the form of a wire and forms a plus electrode, and a discharge electrode which is arranged at a predetermined height difference from the discharge wire to form a minus pole Wherein the dust collecting portion is formed by a plurality of high-voltage collecting electrode plates and a plurality of grounding electrode plates arranged alternately with each other.

In order to generate a discharge between the discharge wire and the ground electrode plate, such a conventional electric dust collector requires a high voltage to be applied to the discharge wire. Therefore, a large capacity power supply device for applying a high voltage is required. Consumed.

As described above, since a high voltage is applied to the discharge electrode, it is difficult to reduce the size of the electrostatic precipitator to a certain level or less, because the discharge wire and the dust collecting unit must be spaced sufficiently apart from each other in consideration of safety.

One aspect of the present invention is to provide an electrostatic precipitator and its electrode plate which are formed to have a thinner size and can utilize the space more efficiently.

Another aspect of the present invention is to provide an electrostatic precipitator and an electrode plate for enhancing the charging efficiency of contaminants such as dust by including an electrode layer used as a dust collecting electrode even in a charging area.

Another aspect of the present invention is to provide an electrostatic precipitator and its electrode plate capable of reducing the total number of electrode plates by increasing the space between adjacent electrodes.

Another aspect of the present invention is to provide an electrostatic precipitator in which the space between the electrodes is relatively enlarged, so that the pressure loss is reduced and the electrostatic precipitator can be used in a large air volume.

The electrostatic precipitator according to an embodiment of the present invention includes a high voltage electrode plate and a low voltage electrode plate alternately stacked to form a charging region and a dust collecting region along the air flow direction, And a dust collecting electrode disposed over the charging area and the dust collecting area so as to collect the contaminant charged in the dust collecting area, wherein the dust collecting electrode and the ground electrode Is characterized by increasing the strength of the electric field of the charging area.

The high voltage electrode plate includes first and second film members formed of an insulating material and adhered to each other, a first electrode layer provided on the outer surface of the first and second film members to form a discharge electrode, And a second electrode layer provided between the film members to form a dust collecting electrode.

The high-voltage electrode plate may include first and second film members formed of an insulating material and adhered to each other, and a second film member disposed between the first and second film members, and a part thereof protruding outside the first and second film members And an electrode layer for forming a discharge electrode and a dust collecting electrode.

Further, the first electrode layer is characterized in that carbon ink is printed on the outer surfaces of the first and second film members, respectively.

The second electrode layer is characterized in that one end of the second electrode layer is disposed adjacent to the first electrode layer.

The second electrode layer includes a first portion formed on the downstream side in the flow direction of air in a straight line connecting one end of the first electrode layer formed on the first film member and one end of the first electrode layer formed on the second film member .

The second electrode layer may further include a second portion disposed in a straight line upstream from the flow direction of the air.

The second electrode layer is characterized in that at least a part of the second electrode layer is provided so as to face the first electrode layer in a direction in which the high voltage electrode plate is laminated.

The electrode layer includes a first portion for forming a discharge electrode at an end portion within a few mm protruding outwardly and a second portion for forming a dust collecting electrode at a portion excluding the protruding end portion.

Further, the electrode layer is formed of a conductive fiber.

The electrostatic precipitator according to an embodiment of the present invention includes a high voltage electrode plate and a low voltage electrode plate spaced apart from each other to form a charging region and a dust collecting region along the air flow direction, A first high voltage electrode plate having an electrode and a dust collecting electrode formed thereon and disposed in a charging section and a dust collecting section; and a second high voltage electrode plate formed only in the dust collecting section and disposed in the dust collecting section, A first low-voltage electrode plate which is formed in the charging area and the dust-collecting area, in which counter electrodes and ground electrodes are formed so as to correspond to the electrode plates, and a second low-voltage electrode plate formed only in the dust- The electric field formed between the dust collecting electrode of the first high voltage electrode plate and the ground electrode of the first low voltage electrode plate includes a low voltage electrode plate, It characterized in that for increasing the strength of the electric field in the charging zone region formed between the discharge electrode and the first counter electrode of the low-voltage electrode plates.

Further, the dust collecting electrode of the first high voltage electrode plate is arranged in the charging section area.

The discharge electrode of the first high voltage electrode plate is formed by a first electrode layer printed on the outer surface of a pair of plastic resin by carbon coating and the dust collecting electrode of the first high voltage electrode plate is connected to a pair of plastics And a second electrode layer disposed between the resin layers.

Further, the discharge electrode of the first high-voltage electrode plate is formed by the end portion of the electrode layer protruding between the pair of plastic resins, and the dust collecting electrode of the first high-voltage electrode plate is formed by the portion excluding the end portion of the electrode layer .

The second high voltage electrode plate and the second low voltage electrode plate are arranged in at least one pair between the first high voltage electrode plate and the first low voltage electrode plate.

The electrode plate of the electrostatic precipitator according to the embodiment of the present invention includes a discharge electrode disposed on the upstream side in the air flow direction to discharge contaminants and a discharge electrode disposed on the upstream side in the air flow direction to the downstream side in the air flow direction, And the electric field formed by the dust collecting electrode increases the intensity of the electric field formed by the discharging electrode.

The electrode plate includes first and second film members formed of an insulating material and attached to each other, a first electrode layer printed on the outer surfaces of the first and second film members to form a discharge electrode, And a second electrode layer provided between the film members to form a dust collecting electrode.

In addition, the electrode plate may include first and second film members formed of an insulating material and attached to each other, and a second film member disposed between the first and second film members, and a part thereof protruding outside the first and second film members, And an electrode layer for forming the electrode and the dust collecting electrode.

Therefore, the electric dust collecting apparatus according to the embodiment of the present invention includes both the discharge electrode for charging the high voltage electrode plate with the contaminants and the dust collecting electrode for collecting the charged contaminants on the low voltage electrode plate. The width is greatly reduced, and the space can be used more efficiently.

Also, since the electrode layer used as the dust collecting electrode is included in the charging area, the charging efficiency of the pollutant such as dust can be improved.

1 is a perspective view showing an electric dust collector according to an embodiment of the present invention.
FIG. 2 is a schematic view showing the arrangement of a high voltage electrode and a low voltage electrode applied to the electric dust collector of FIG. 1;
3 is a perspective view showing the first high voltage electrode plate shown in FIG.
4 is a plan view of the first high voltage electrode plate shown in FIG.
5 is a side view of the first high voltage electrode plate shown in FIG.
6 is a side view showing a modification of the first high voltage electrode plate shown in FIG.
7 is a schematic view showing the arrangement of a high-voltage electrode and a low-voltage electrode applied to an electric dust collector according to another embodiment of the present invention.
8 is a perspective view showing the first high voltage electrode plate shown in FIG.
9 is a plan view showing the first high voltage electrode plate shown in FIG.
10 is a side view showing the first high voltage electrode plate shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of an electric dust collector according to an embodiment of the present invention, and FIG. 2 is a schematic view showing the arrangement of a high voltage electrode and a low voltage electrode applied to the electric dust collector of FIG.

1 and 2, an electric dust collector 1 according to an embodiment of the present invention is disposed on a flow path through which air flows and collects contaminants such as dust contained in air. A frame 100 provided on both sides thereof with lattice-shaped communication holes 100a so as to allow the air to flow therethrough in one direction, and a plurality of high-voltage Electrode plate 200 and a plurality of low-voltage electrode plates 300 formed to correspond to the high-voltage electrode plate 200.

The high voltage electrode plate 200 and the low voltage electrode plate 300 according to the embodiment of the present invention have a constant height difference so that the charging area 10 and the dust collection area 20 are formed along the air flow direction D Are alternately stacked.

The high voltage electrode plate 200 is provided with a discharge electrode 10A to which a high voltage is applied so that the contaminants contained in the air are charged in the charging region 10 and a discharge electrode 10B to which high voltage is applied so as to collect contaminants charged in the dust collecting region 20 The dust collecting electrode 20A is formed. Here, the discharge electrode 10A and the dust collecting electrode 20A may be connected to each other by a different high voltage power source 500. [

The low voltage electrode plate 300 is provided with a counter electrode 10B provided at a predetermined height difference from the discharge electrode 10A in order to form a corona discharge in the charging area 10, A ground electrode 20B is formed so as to form a constant electric field between the ground electrode 20A and the ground electrode 20B.

Voltage electrode plate 200 serves as both the discharge electrode and the dust collecting electrode of the two-stage electrostatic precipitator type electrostatic precipitator and the low voltage electrode plate 300 serves as the discharge electrode of the two-stage electrostatic precipitator type electrostatic precipitator, And serves also as an electrode.

The high voltage electrode plate 200 includes a first high voltage electrode plate 210 having a discharge electrode 10A and a dust collecting electrode 20A and a second high voltage electrode plate 210 having a discharge electrode 10A, And a high voltage electrode plate 220.

The low voltage electrode plate 300 includes a first low voltage electrode plate 310 having a counter electrode 10B and a ground electrode 20B formed to correspond to the first high voltage electrode plate 210, And a second low voltage electrode plate 320 formed only of the ground electrode 20B so as not to correspond to the counter electrode 10B.

The second high-voltage electrode plate 220 and the second low-voltage electrode plate 320 are paired with each other. At least one pair of the second high-voltage electrode plate 220 and the second low- And is disposed between the high voltage electrode plate 210 and the first low voltage electrode plate 310.

For example, as shown in FIG. 2, a pair of a second high voltage electrode plate 220 and a second low voltage electrode plate (not shown) are disposed between the first high voltage electrode plate 210 and the first low voltage electrode plate 310 320 may be disposed.

The first high voltage electrode plate 210 and the first low voltage electrode plate 310 are connected to the second high voltage electrode plate 220 and the second low voltage electrode plate 320 so as to correspond to the length corresponding to the charging area 10, ) Is relatively longer than that of the second embodiment.

When a high voltage is applied to the first and second high voltage electrode plates 210 and 220 from the high voltage power source 500, the first and second high voltage electrode plates 210 and 220 and the first and second low voltage electrode plates 310 and 320, The dust collecting apparatus 1 can constitute the charging section area 10 which is an area for charging the dust particles in the air and the dust collecting section area 20 which is the area for collecting the charged dust particles in the charging section area 10 .

Therefore, the electric dust collector 1 according to the embodiment of the present invention can eliminate a separate space for installing the discharge electrode plate and the ground electrode plate, which is applied to the electric dust collector of the two-stage electric dust collection system, The size of the electric dust collector 1 can be greatly reduced.

FIG. 3 is a perspective view showing the first high voltage electrode plate shown in FIG. 2, FIG. 4 is a plan view showing the first high voltage electrode plate shown in FIG. 3, Fig.

2 to 5, the first high voltage electrode plate 210 according to an embodiment of the present invention includes first and second film members 211 and 212 formed of an insulating material and attached to each other, A first electrode layer 213 provided on the outer surfaces of the first and second film members 211 and 212 to form a discharge electrode 10A and a second electrode layer 213 provided between the first and second film members 211 and 212 to form a dust collecting electrode 20A And a second electrode layer 214.

5, the first electrode layer 213 is disposed on the upstream side D1 of the air flow direction to discharge contaminants such as dust. The first electrode layer 213 is formed on the first and second films 213 and 214, And the outer surfaces of the members 211 and 212 may be respectively formed by a carbon ink printing method.

The second electrode layer 214 is disposed between the first and second film members 211 and 212 so as to extend from the upstream side D1 in the air flow direction to the downstream side D2 in the air flow direction, And collects contaminants such as charged dust.

The second electrode layer 214 is formed such that one end of the second electrode layer 214 on the upstream side in the air flow direction D1 is adjacent to the first electrode layer 213.

For example, the second electrode layer 214 may include one end 213A of the first electrode layer 213 formed on the first film member 211 and one end 213A of the first electrode layer 213 formed on the second film member 212 A first portion 214A disposed on the downstream side D2 of the air in the imaginary line X with respect to the imaginary line X connecting the connecting portions 213A and 213A and the first portion 214A disposed on the upstream side D1 in the air flow direction And a second portion 214B.

That is, at least a part of the second electrode layer 214 is provided so as to face the first electrode layer 213 in a direction in which the high voltage electrode plate 200 is laminated, and when a high voltage is applied to the second electrode layer 214, The electric field formed in the first portion 214A of the second electrode layer 214 affects the first electrode layer 213 as well as the second portion 214B of the second electrode layer 214 so that the amount of charge of contaminants such as dust can be increased do.

As a result, the first electrode layer 213 for forming the discharge electrode 10A and the second electrode layer 214 for forming the dust collecting electrode 20A are included in the charging area 10 where the contaminants such as dust are charged So that the particle charging efficiency can be increased.

6, the second electrode layer 214 is formed on one end 213A of the first electrode layer 213 formed on the first film member 211 and on the first electrode layer 213 formed on the second film member 212, Only the first portion 214A disposed on the downstream side D2 of the air in the imaginary line X with respect to the imaginary line X connecting one end 213A of the air intake passage 213 is provided.

Even in this case, the first portion 214A of the second electrode layer 214 forming the dust collecting electrode 20A may affect the first electrode layer 213 forming the discharge electrode 10A, It is possible to increase the particle charging efficiency.

Therefore, since the interval between the first high voltage electrode plate 210 and the second low voltage electrode plate 320 including the first electrode layer 213 forming the discharge electrode 10A can be increased, The number of the electrode plates 210, 220, 310, and 320 to be disposed can be reduced, so that the material cost can be reduced and the pressure loss can be reduced.

For example, when the interval between the second high voltage electrode plate 220 and the first low voltage electrode plate 310 shown in FIG. 2 or the interval between the second high voltage electrode plate 220 and the second low voltage electrode plate 320 is L The interval between the first high voltage electrode plate 210 and the second low voltage electrode plate 320 can be set to 1.2L to 1.5L.

In addition, since the particle charging efficiency is not greatly reduced even when the flow rate is increased, the charging efficiency of the dust can be increased even at a high cross-sectional velocity of 2.5 m / sec or more.

Next, a process of charging and collecting contaminants such as dust by the high-voltage electrode plate and the low-voltage electrode plate will be described.

First, when a positive high voltage power source 500 is applied to the first and second high voltage electrode plates 210 and 220, the first high voltage electrode plate 210 forming the discharge electrode 10A and the first electrode layer 213, The corona discharge is generated between the charging area 300 and the contaminant in the air passing through the charging area 10 is positively charged.

At this time, the electric field of the second electrode layer 214 of the first high voltage electrode plate 210 forming the dust collecting electrode 20A affects the charging area 10, and the electric field intensity in the charging area 10 increases The particle charging efficiency is increased, so that the charged particles can travel a great distance in the course of passing through the charging region 10. [

When the charged contaminant passes through the charging region 10 and the air and moves to the dust collecting region 20, the contaminants such as positively charged dust and the like are supplied to the low voltage electrode plate 300, Voltage electrode plate 300 and is collected by the ground electrode 20B of the low-

The polarity of the high voltage power supply 500 may be either positive or negative, and may also be a pulse voltage. Reference numeral 40 denotes an air blowing unit for allowing a flow of air to be formed in the electric dust collector.

Another embodiment of the present invention will be described with reference to Figs. 7 to 10. Fig. The same reference numerals are given to the same components as those of the first embodiment, and a description thereof will be omitted.

FIG. 7 is a schematic view showing the arrangement of a high voltage electrode and a low voltage electrode applied to the electric dust collector according to another embodiment of the present invention, FIG. 8 is a perspective view showing the first high voltage electrode plate shown in FIG. 8 is a plan view showing the first high voltage electrode plate shown in FIG. 8, and FIG. 10 is a side view showing the first high voltage electrode plate shown in FIG.

7 to 10, an electric dust collector 1 'according to another embodiment of the present invention includes a plurality of high voltage electrode plates 200' disposed in a frame (not shown) for collecting contaminants such as dust, And a plurality of low voltage electrode plates 300 formed so as to correspond to the high voltage electrode plates 200 'and alternately arranged with the plurality of high voltage electrode plates 200'.

The high voltage electrode plate 200 'of the electric dust collector 1' according to another embodiment of the present invention serves also as a discharge electrode and a dust collecting electrode of the electric dust collector of the two-stage electric dust collector type, Serves also as a counter electrode and a ground electrode of the electric dust collector of the two-stage electric dust collection system.

The high voltage electrode plate 200 'and the low voltage electrode plate 300 according to another embodiment of the present invention may have a constant height difference < RTI ID = 0.0 > Are stacked alternately with each other.

The high voltage electrode plate 200 'includes a first high voltage electrode plate 210' having a discharge electrode 10'A and a dust collecting electrode 20A and a discharge electrode 10'A, Voltage electrode plate 300 includes a first high voltage electrode plate 210 and a second high voltage electrode plate 220. The low voltage electrode plate 300 includes a first high voltage electrode plate 210, Voltage electrode plate 310 and a second low-voltage electrode plate 320 formed only of the dust-collecting electrode 20A so as not to correspond to the counter electrode 10B so as to correspond to the second high-voltage electrode plate 220. [

The first high voltage electrode plate 210 'includes first and second film members 211' and 212 'formed of an insulating material and adhered to each other, and a first high voltage electrode plate 210' between the first and second film members 211 'and 212' And an electrode layer 213 'partially provided on the first and second film members 211' and 212 '.

The electrode layer 213 'may be formed of fine conductive fibers such as carbon fibers or carbon nanotubes having a diameter ranging from several micrometers to several tens of micrometers. The electrode layer 213' may include first and second electrodes 213 ' 2 are partially protruded in the process of attaching the film members 211 'and 212'.

The electrode layer 213 'includes a first portion 213'A that forms the discharge electrode 10'A at an end within a few millimeters protruding to the outside and a second portion 213'A that forms the dust collecting electrode 20A at a portion excluding the protruded end portion And a second portion 213'B that is adapted to be received.

Accordingly, the first portion 213'A of the electrode layer 213 'becomes the discharge electrode 10'A causing the corona discharge to occur between the first portion 213'A and the counter electrode 10B, To form regions 10 '.

As a result, when a high voltage is applied to the electrode layer 213 'of the high voltage electrode plate 210', a corona discharge is generated between the counter electrode 10B and the opposing electrode 10B of the low voltage electrode plate 300, So that pollutants such as dust are charged.

In the second portion 213'B of the electrode layer 213 'forming the dust collecting electrode 20A, a dust collecting portion region 20 for collecting charged contaminants in the charging region 10' is formed .

At this time, the electric field generated in the second portion 213'B of the electrode layer 213 'forming the dust collecting electrode 20A affects the charging region 10', and the electric field in the charging region 10 ' As the intensity increases, the particle charging efficiency increases, so that the charged particles can travel a great distance in the course of passing through the charging area 10 '.

Therefore, as shown in FIG. 7, the first high voltage electrode plate 210 'and the second low voltage electrode plate 320 including the first electrode layer 213' A forming the discharge electrode 10'A The number of the electrode plates 210 ', 220, 310 and 320 disposed in the electric dust collector 1' can be reduced, so that the material cost can be reduced and the pressure loss can be reduced.

For example, if the interval between the second high voltage electrode plate 220 and the first low voltage electrode plate 310 or the interval between the second high voltage electrode plate 220 and the second low voltage electrode plate 320 is L, The interval between the plate 210 'and the second low voltage electrode plate 320 can be set to 1.2L to 1.5L.

If the electrode layer 213 'is made of a fine conductive fiber, the discharge can be generated even at a low voltage, so that the capacity of the high voltage power source 500 used in the electrostatic precipitator 1' can be reduced, Can also be reduced.

As described above, in the electric dust collecting apparatus according to the embodiment of the present invention, the electric field of the dust collecting electrode forming the dust collecting section region in the charging section region where the contaminants such as dust are charged becomes larger, It is understood that the basic technical idea is to make it possible. Therefore, many modifications may be made by those skilled in the art without departing from the scope and spirit of the present invention.

1 ... Electrostatic precipitator 10 .. Charging area
10A ... discharge electrode 20 ... dust collecting region
20A ... collecting electrode 100 ... frame
200 ... high voltage electrode plate 210 .. first high voltage electrode plate
220 ... second high voltage electrode plate 300 ... low voltage electrode plate
310 ... first low-voltage electrode plate 320 ... second low-voltage electrode plate
400 ... blowing unit 500 ... high voltage power source

Claims (18)

A high voltage electrode plate and a low voltage electrode plate alternately stacked to form a charging region and a dust collecting region along the air flow direction,
Wherein the high voltage electrode plate includes a discharge electrode for causing a discharge between the high voltage electrode plate and the counter electrode so that contaminants are charged in the area of the charging unit and a discharge electrode for discharging the contaminant from the charging area and the dust collecting area, And a dust collecting electrode disposed therein,
Wherein an electric field formed between the dust collecting electrode and the ground electrode increases the intensity of the electric field in the charging area. The method according to claim 1,
Wherein the high voltage electrode plate comprises first and second film members formed of an insulating material and attached to each other, a first electrode layer provided on the outer surface of the first and second film members to form the discharge electrode, And a second electrode layer provided between the second film members and forming the dust collecting electrode. The method according to claim 1,
Wherein the high voltage electrode plate comprises first and second film members formed of an insulating material and attached to each other, and a second film member disposed between the first and second film members, wherein a part thereof protrudes to the outside of the first and second film members And an electrode layer for forming the discharge electrode and the dust collecting electrode. 3. The method of claim 2,
Wherein the first electrode layer is printed with carbon ink on the outer surfaces of the first and second film members, respectively. 3. The method of claim 2,
Wherein one end of the second electrode layer is disposed adjacent to the first electrode layer. 3. The method of claim 2,
The second electrode layer includes a first portion formed on the downstream side in the flow direction of air in a straight line connecting one end of the first electrode layer formed on the first film member and one end of the first electrode layer formed on the second film member Wherein the electric dust collecting device comprises: The method according to claim 6,
Wherein the second electrode layer further comprises a second portion disposed upstream from the straight line in the direction of air flow. 3. The method of claim 2,
Wherein at least a portion of the second electrode layer is provided to face the first electrode layer in a direction in which the high voltage electrode plate is stacked. The method of claim 3,
Wherein the electrode layer includes a first portion forming the discharge electrode at an end portion within a few mm protruding outwardly and a second portion forming the dust collecting electrode at a portion excluding the protruding end portion, Device. 10. The method of claim 9,
Wherein the electrode layer is formed of a conductive fiber. A high voltage electrode plate and a low voltage electrode plate spaced apart from each other to form a charging region and a dust collecting region along the air flow direction,
Wherein the high voltage electrode plate includes a first high voltage electrode plate having a discharge electrode and a dust collecting electrode formed thereon and disposed in the charging section and the dust collecting section area and a second high voltage electrode plate formed only in the dust collecting section, ,
The low-voltage electrode plate includes: a first low-voltage electrode plate having opposing electrodes and a ground electrode formed to correspond to the first high-voltage electrode plate and disposed in the charging area and the dust collection area; And a second low-voltage electrode plate disposed on the dust collecting area,
Wherein an electric field formed between the dust collecting electrode of the first high voltage electrode plate and the ground electrode of the first low voltage electrode plate is formed between the discharge electrode of the first high voltage electrode plate and the opposite electrode of the first low voltage electrode plate, And increases the intensity of the electric field of the sub-area. 12. The method of claim 11,
And the dust collecting electrode of the first high voltage electrode plate is disposed in the charging section area. 12. The method of claim 11,
Wherein a discharge electrode of the first high voltage electrode plate is formed by a carbon-coated first electrode layer on an outer surface of a pair of plastic resins,
Wherein the dust collecting electrode of the first high voltage electrode plate is formed by a second electrode layer disposed between the pair of plastic resins so as to be adjacent to the first electrode layer. 12. The method of claim 11,
The discharge electrode of the first high voltage electrode plate is formed by the end portion of the electrode layer protruding between the pair of plastic resins,
Wherein the dust collecting electrode of the first high voltage electrode plate is formed by a portion excluding the end portion of the electrode layer. 12. The method of claim 11,
Wherein the second high voltage electrode plate and the second low voltage electrode plate are disposed in at least one pair between the first high voltage electrode plate and the first low voltage electrode plate. A discharge electrode disposed on the upstream side in the air flow direction to discharge the pollutant,
And a dust collecting electrode disposed upstream from the upstream side in the air flow direction and downstream in the air flow direction for collecting the charged contaminants,
Wherein the electric field formed by the dust collecting electrode increases the strength of the electric field formed by the discharge electrode. 17. The method of claim 16,
Wherein the high voltage electrode plate comprises first and second film members formed of an insulating material and attached to each other, a first electrode layer printed on the outer surfaces of the first and second film members to form the discharge electrode, And a second electrode layer provided between the second film member and forming the dust collecting electrode. 17. The method of claim 16,
The high-voltage electrode plate includes first and second film members formed of an insulating material and adhered to each other, and a second film member disposed between the first and second film members, and a part thereof protruding outside the first and second film members And an electrode layer forming the discharge electrode and the dust collecting electrode.

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